PrP的胞内运输与朊病毒病

朊病毒病,即传染性海绵状脑病（transmissible spongiform encephalopathies,TSEs）,是一类致死性的神经退行性疾病,存在散发性、感染性和遗传性3种形式。在朊病毒病的病理过程中,细胞正常朊蛋白PrPc（cellular PrP）转化为异常构象的PrP^Sc（scrapie PrP）是至关重要的,但是朊病毒的增殖如何导致神经元凋亡仍不清楚。PrPc的胞内运输在朊病毒病中发挥重要作用,朊病毒感染后PrP^C转化为PrP^Sc,及遗传性朊病毒病中PrP突变可能影响PrP的生物合成、亚细胞定位及转运过程,通过干扰PrP^C的正常功能或产生毒性中间体而导致神经系统病变。现对近年来关于PrP胞内运输在朊病毒病中的作用进行综述。     

朊病毒感染中钙调蛋白相关激酶含量异常变化的研究

朊病毒病是一类具有致死性、传染性和进行性的神经退行性疾病。目前研究发现许多因子都参与了疾病的发生发展过程,包括细胞因子、激酶和一些离子,其中钙离子及相关激酶在朊病毒病致病机制中的研究报道较少,为了探究朊病毒感染中钙调蛋白相关下游激酶的含量变化情况,本研究利用多种检测方法对朊病毒感染细胞系及小鼠脑组织进行了分析。结果显示朊病毒感染后,钙离子和钙调蛋白(CaM)的表达水平升高,下游Ca²⁺/CaM复合物依赖性激酶CaMKIα和CaMKIV表达水平下降,同时这些激酶的上游激酶CaMKKα含量降低,提示朊病毒感染后神经元中钙离子和相关激酶稳态失衡,这种异常变化很可能影响下游多种转录因子合成,这些结果为解释朊病毒感染后神经元大量丢失提供了科学依据。     

微小RNA在朊病毒病等神经退行性疾病中的研究进展

朊病毒病是一类具有传染性、不可逆且致命的神经退行性疾病,其致病机制为体内正常编码的细胞型朊蛋白(cellular prion protein,PrP~C)构象发生变化,形成了具有感染性的异常痒病型朊病毒(scrapie prion protein,PrP~(Sc)),但具体机制不清楚,目前为止尚无有效治疗方法。微小RNA(microRNA,miRNA)可在转录水平调控细胞蛋白表达,对神经系统发育及功能起重要作用。近年来,对一些特定miRNA在朊病毒病中相应调控机制、自发免疫、炎症信号转导及靶基因预测方面的研究可为治疗朊病毒病提供新的角度。本文就miRNA在朊病毒病发生中的相关研究进展进行综述,并详细探讨其中研究较为深入的miRNA。     

阿尔茨海默病的脑神经元凋亡机制

阿尔茨海默病（AD）是一种中枢神经系统退行性疾病,临床主要表现为认知功能障碍、行为异常及日常生活能力下降,主要神经病理改变有神经元变性、丢失引起的脑萎缩,细胞外的老年斑（senile plaque,SP）和细胞内的神经元纤维缠结（neurofibrillary tangle,NFT）.细胞凋亡与AD有密切的关系,β淀粉样蛋白（Aβ）在此过程中可能有重要的作用.近年来的研究还指出,细胞周期的异常可能是AD发生的较早期事件,这种异常的细胞周期也可导致细胞的凋亡,最终引发AD.该文介绍细胞周期异常和Aβ介导的细胞凋亡机制作一综述.     

朊蛋白相关蛋白Shadoo与朊病毒病

朊病毒病,即传染性海绵状脑病（transmissible spongiform encephalopathies, TSEs）,是一类传染性、致死性神经退行性疾病。在朊病毒病的病理过程中,细胞正常朊蛋白PrP。转化为异常构象的PrP是至关重要的,但是PrP‘的正常生理功能仍不清楚。国外学者利用比较基因组学发现了-个新的朊蛋白相关蛋白-shadoo（Sho）。Sho与PrP。在氨基酸序列和细胞定位的相似性及主要在脑组织表达,使它成为-个非常值得研究的PrP相关蛋白。对Sho可能存在的与PrP。重叠的功能甚至直接相互作用的研究工作,将对今后揭示PrPc正常生理功能以及揭示Pfion病发病机制具有重要现实意义。     

靶向PrP及Aβ的治疗性抗体研究进展

朊病毒病与阿尔茨海默病具有蛋白质异常折叠的共同特征, 患者均有痴呆的症状, 但前者具有传染性, 而后者没有. 这引起人们的研究兴趣, 从不同角度开展了二者的比较研究. 近年来, 靶向其关键蛋白PrP和Aβ的免疫治疗研究进展很快. 本文结合实际研究工作, 着眼于治疗性抗体的疾病靶向性和构象特异性等主要特征, 综述了针对PrP和Aβ治疗性抗体研究中的新视点和新策略, 以期为探索这两种疾病的共同机制及治疗方法提供参考.     

蛋白质错误折叠循环扩增技术

目前发现有多种人类及动物疾病是由体内蛋白质的错误折叠引起的,其中朊毒粒病因具有传染性而备受关注.朊毒粒病研究的核心问题之一是正常细胞朊蛋白（PrPc）向异常致病朊毒粒（PrPsc）转变的机制.蛋白质错误折叠循环扩增技术（protein misfolding cyclic amplification,PMCA）就是最新发明的在体外诱导朊蛋白（PrPc）产生错误折叠生成朊毒粒（prpsc）的技术.该文将概要介绍此项技术的原理、技术要点及在诊断与基础研究方面的应用前景.     

朊病毒病治疗方法的研究进展

朊病毒是一种由体内正常朊蛋白转化形成的传染性蛋白质,朊病毒病是由朊病毒引发的致命性神经退行性疾病。目前临床虽然尚无治疗朊病毒病的方法,但是大量的研究者已从多个角度进行研究,并取得了一定进展。对近期有关传统化学药物、基因治疗方法、免疫学治疗方法和同源朊蛋白的朊病毒病治疗方法进行了综述,并重点分析了新型靶向细胞内信号通路药物以及有潜在利用价值的线粒体相关朊病毒胞内作用信号通路,旨在为朊病毒新的研究方向提供理论依据,从而促进朊病毒病治疗方法应用于临床。     

朊病毒中朊蛋白及朊蛋白现象

朊病毒病是一种由朊病毒侵染动物神经系统并引发神经退行性症状的传染性疾病。朊病毒是由正常朊蛋白PrP^C通过构象转化形成具蛋白酶抗性的异常朊蛋白PrP^Se的病原微生物。最新研究表明,朊蛋白通过构象转变形成新的功能分子的现象在生物界中普遍存在,并与正常生物功能密切相关。通过研究类朊蛋白现象可以有助于揭示朊病毒感染机制以及深化对生物遗传多样性的了解。     

胰岛淀粉样多肽诱导β细胞凋亡机制的研究进展

2型糖尿病病变中由人类胰岛淀粉样多肽(hIAPP)形成的蛋白纤维沉淀被认为是引起β细胞凋亡的重要原因。目前,hIAPP诱导β细胞凋亡的确切机制尚未完全明了,很多研究显示hIAPP引起的β细胞膜破裂是hIAPP产生细胞毒性的主要原因。不仅hIAPP具有引起膜损伤,从而导致细胞淀粉样改变的细胞毒性机制,一些与错误折叠疾病(如阿尔兹海默病、帕金森综合征、朊病毒病等)相关的多肽和蛋白质也具有相同的细胞毒性机理。结合最新研究进展,讨论了hIAPP与膜的相互作用,阐述了hIAPP诱导β细胞凋亡的几种可能机制。     

Mayhem of the multiple mechanisms: modelling neurodegeneration in prion disease

This review examines recent attempts to advance the understanding of the mechanism by which neurones die in prion disease. Prion diseases or transmissible spongiform encephalopathies are characterized by the conversion of a normal glycoprotein, the prion protein, to a protease-resistant form that is suggested to be both the infectious agent and the cause of the rapid neurodegeneration in the disease. Death of the patient results from this widespread neuronal loss. Thus understanding the mechanism by which the abnormal form of the prion protein causes neuronal death might lead to treatments that would prevent the life-threatening nature of these diseases.     

蛋白质错误折叠循环扩增及其在朊病毒蛋白检测中的应用研究进展

朊病毒蛋白（prion protein,PrP）是传染性海绵状脑病的病原体,其检测是该病诊断的重要依据。该文从原理、方法、影响因素和检测应用方面对蛋白质错误折叠循环扩增（protein mis-folding cyclic amplification,PMCA）这种朊病毒蛋白新型检测技术做了介绍,旨在为朊病毒蛋白的检测和发病机制研究提供理论参考。     

Caspase-12 and endoplasmic reticulum stress mediate neurotoxicity of pathological prion protein

Prion diseases are characterized by accumulation of misfolded prion protein (PrP(Sc)), and neuronal death by apoptosis. Here we show that nanomolar concentrations of purified PrP(Sc) from mouse scrapie brain induce apoptosis of N2A neuroblastoma cells. PrP(Sc) toxicity was associated with an increase of intracellular calcium released from endoplasmic reticulum (ER) and up-regulation of several ER chaperones. Caspase-12 activation was detected in cells treated with PrP(Sc), and cellular death was inhibited by overexpression of a catalytic mutant of caspase-12 or an ER-targeted Bcl-2 chimeric protein. Scrapie-infected N2A cells were more susceptible to ER-stress and to PrP(Sc) toxicity than non-infected cells. In scrapie-infected mice a correlation between caspase-12 activation and neuronal loss was observed in histological and biochemical analyses of different brain areas. The extent of prion replication was closely correlated with the up-regulation of ER-stress chaperone proteins. Similar results were observed in humans affected with sporadic and variant Creutzfeldt-Jakob disease, implicating for the first time the caspase-12 dependent pathway in a neurodegenerative disease in vivo, and thus offering novel potential targets for the treatment of prion disorders.     

Globular and pre-fibrillar prion aggregates are toxic to neuronal cells and perturb their electrophysiology

Prion diseases are characterised at autopsy by neuronal loss and accumulation of amorphous protein aggregates and/or amyloid fibrils in the brains of humans and animals. These protein deposits result from the conversion of the cellular, mainly alpha-helical prion protein (PrP(C)) to the beta-sheet-rich isoform (PrP(Sc)). Although the pathogenic mechanism of prion diseases is not fully understood, it appears that protein aggregation is itself neurotoxic and not the product of cell death. The precise nature of the neurotoxic species and mechanism of cell death are yet to be determined, although recent studies with other amyloidogenic proteins suggest that ordered pre-fibrillar or oligomeric forms may be responsible for cellular dysfunction. In this study we have refolded recombinant prion protein (rPrP) to two distinct forms rich in beta-sheet structure with an intact disulphide bond. Here we report on the structural properties of globular aggregates and pre-fibrils of rPrP and show that both states are toxic to neuronal cells in culture. We show that exogenous rPrP aggregates are internalised by neuronal cells and found in the cytoplasm. We also measured the changes in electrophysiological properties of cultured neuronal cells on exposure to exogenous prion aggregates and discuss the implications of these findings.     

Early Increase and Late Decrease of Purkinje Cell Dendritic Spine Density in Prion-Infected Organotypic Mouse Cerebellar Cultures

Prion diseases are infectious neurodegenerative diseases associated with the accumulation of protease-resistant prion protein, neuronal loss, spongiform change and astrogliosis. In the mouse model, the loss of dendritic spines is one of the earliest pathological changes observed in vivo, occurring 4–5 weeks after the first detection of protease-resistant prion protein in the brain. While there are cell culture models of prion infection, most do not recapitulate the neuropathology seen in vivo. Only the recently developed prion organotypic slice culture assay has been reported to undergo neuronal loss and the development of some aspects of prion pathology, namely small vacuolar degeneration and tubulovesicular bodies. Given the rapid replication of prions in this system, with protease-resistant prion protein detectable by 21 days, we investigated whether the dendritic spine loss and altered dendritic morphology seen in prion disease might also develop within the lifetime of this culture system. Indeed, six weeks after first detection of protease-resistant prion protein in tga20 mouse cerebellar slice cultures infected with RML prion strain, we found a statistically significant loss of Purkinje cell dendritic spines and altered dendritic morphology in infected cultures, analogous to that seen in vivo. In addition, we found a transient but statistically significant increase in Purkinje cell dendritic spine density during infection, at the time when protease-resistant prion protein was first detectable in culture. Our findings support the use of this slice culture system as one which recapitulates prion disease pathology and one which may facilitate study of the earliest stages of prion disease pathogenesis.     

Perturbation of endoplasmic reticulum homeostasis facilitates prion replication

Prion diseases are fatal and infectious neurodegenerative disorders characterized by the accumulation of an abnormally folded form of the prion protein (PrP), termed PrP(Sc). Prion replication triggers endoplasmic reticulum (ER) stress, neuronal dysfunction, and apoptosis. In this study we analyze the effect of perturbations in ER homeostasis on PrP biochemical properties and prion replication. ER stress led to the generation of a mis-folded PrP isoform, which is detergent-insoluble and protease-sensitive. To understand the mechanism by which ER stress generates PrP misfolding, we assessed the contribution of different signaling pathways implicated in the unfolded protein response. Expression of a dominant negative form of IRE1 alpha or XBP-1 significantly increased PrP aggregation, whereas overexpression of ATF4 or an active mutant form of XBP-1 and ATF6 had the opposite affect. Analysis of prion replication in vitro revealed that the PrP isoform generated after ER stress is more efficiently converted into PrP(Sc) compared with the protein extracted from untreated cells. These findings indicate that ER-damaged cells might be more susceptible to prion replication. Because PrP(Sc) induces ER stress, our data point to a vicious cycle accelerating prion replication, which may explain the rapid progression of the disease.     

Prion protein gene-deficient cell lines: powerful tools for prion biology

Prion diseases are zoonotic infectious diseases commonly transmissible among animals via prion infections with an accompanying deficiency of cellular prion protein (PrP(C)) and accumulation of an abnormal isoform of prion protein (PrP(Sc)), which are observed in neurons in the event of injury and disease. To understand the role of PrP(C) in the neuron in health and diseases, we have established an immortalized neuronal cell line HpL3-4 from primary hippocampal cells of prion protein (PrP) gene-deficient mice by using a retroviral vector encoding Simian Virus 40 Large T antigen (SV40 LTag). The HpL3-4 cells exhibit cell-type-specific proteins for the neuronal precursor lineage. Recently, this group and other groups have established PrP-deficient cell lines from many kinds of cell types including glia, fibroblasts and neuronal cells, which will have a broad range of applications in prion biology. In this review, we focus on recently obtained information about PrP functions and possible studies on prion infections using the PrPdeficient cell lines.     

Copper-dependent functions for the prion protein

Prion diseases such as bovine spongiform encephalopathy and Creutzfeldt-Jakob disease are fatal neurodegenerative diseases. These diseases are characterized by the conversion of a normal cellular protein, the prion protein, to an abnormal isoform that is thought to be responsible for both pathogenesis in the disease and the infectious nature of the disease agent. Understanding the biology and metabolism of the normal prion protein is therefore important for understanding the nature of these diseases. This review presents evidence for the normal function of the cellular prion protein, which appears to depend on its ability to bind copper (Cu). There is now considerable evidence that the prion protein is an antioxidant. Once the prion protein binds Cu, it may have an activity like that of a superoxide dismutase. Conversion of the prion protein to an abnormal isoform might lead to a loss of antioxidant protection that could be responsible for neurodegeneration in the disease.